Absence of nucleosomes in a fraction of SV40 chromatin between the origin of replication and the region coding for the late leader RNA

Electron microscopic examination of SV40 chromatin prepared 44 hr post-infection led to the visualization of a nucleosome-free region (gap) in 15-20% of the minichromosomes. Minichromosomes with and without a gap displayed a mean number of 24 nucleosomes. Measurements carried out on dark field micrographs yielded for the gap a mean length of 249 +/- 13 bp, with a maximum value of 385 bp. The gap was mapped following digestion with three single-cut restriction endonucleases: Bgl l, Bam HI and Eco RI. It was located in the region of the origin of replication in accordance with previous biochemical data. To assess the situ existence of a nucleosome-free region, nuclei from infected cells were digested with DNase I. A highly sensitive region was thus revealed and mapped by secondary digestion with Eco RI. It was located in the same region as the gap, between 0.67 and 0.74 on the physical map. The sensitive region could be detected throughout the late phase of the virus cycle. These findings strongly suggest that a nucleosome-free region exists in the cells. The gap is not likely to be involved in replication, since it is asymmetric with respect to the Bgl I cleavage site, from which replication proceeds symmetrically.     

A stretch of "late" SV40 viral DNA about 400 bp long which includes the origin of replication is specifically exposed in SV40 minichromosomes.

Examination of DNA fragments produced from either formaldehyde-fixed or unfixed SV40 minichromosomes by multiple-cut restriction endonucleases has led to the following major results: Exhaustive digestion of unfixed minichromosomes with Hae III generated all ten major limit-digest DNA fragments as well as partial cleavage products. In striking contrast to this result, Hae III acted on formaldehyde-fixed minichromosomes to yield only one of the limit-digest fragments, F, which is located in the immediate vicinity of the origin of replication, spanning nucleotides 5169 and 250 on the DNA sequence map of Reddy et al. (1978). This 300 base pair (bp) fragment was released as naked DNA from formaldehyde-fixed, Hae III-digested minichromosomes following treatment either by pronase-SDS or by SDS alone. In the latter case, the remainder of the minichromosome retained its compact configuration as assayed by both sedimentational and electrophoretic methods. In minichromosomes, the F fragment is therefore not only accessible to Hae III at its ends, but is also neither formaldehyde cross-linked into any SDS-resistant nucleoprotein structure nor topologically "locked" within the compact minichromosomal particle. This same fragment was preferentially produced during the early stages of digestion of unfixed minichromosomes with Hae III, and its final yield in the exhaustive Hae III digest was significantly higher than that of other limit-digest fragments. Similar results were obtained upon digestion of either unfixed or formaldehyde-fixed minichromosomes with Alu I. In particular, of approximately twenty major limit-digest DNA fragments, only two fragments (F and P, encompassing nucleotides 5146 to 190, and 190 to 325, respectively) were produced by Alu I from the formaldehyde-fixed minichromosomes. All other restriction endonucleases tested (Mbo I, Mbo II, Hind III, Hin II+III and Hinf I), for which there are no closely spaced recognition sequences in the above mentioned regions of the SV40 genome, did not produce any significant amount of limit-digest DNA fragments from formaldehyde-fixed minichromosomes. These findings, taken together with our earlier data on the preferential exposure of the origin of replication in SV40 minichromosomes (Varshavsky, Sundin and Bohn, 1978), strongly suggest that a specific region of the "late" SV40 DNA approximately 400 bp long is uniquely exposed in the compact minichromosome. It is of interest that, in addition to the origin of replication, this region contains binding sites for T antigen (Tjian, 1977), specific tandem repeated sequences and apparently also the promoters for synthesis of late SV40 mRNAs (Fiers et al., 1978; Reddy et al., 1978).     

Interaction of Simian Virus 40 chromatin with Simian Virus 40 T-antigen.

We have studied the binding of the tumor antigen (T-antigen) of simian virus 40 to simian virus 40 chromatin (minichromosomes). The minichromosomes isolated from infected cells by a modification of standard techniques were relatively free of contaminating RNA and cellular DNA and had a ratio (by weight) of protein to DNA of approximately 1; their DNA was 50 to 60% digestible to an acid-soluble form by staphylococcal nuclease. Cleavage of this chromatin with restriction endonucleases indicated that the nuclease-resistant regions were randomly distributed in the population of minichromosomes, but were not randomly distributed within minichromosomes. Only 20 to 35% of these minichromosomes adsorbed nonspecifically to nitrocellulose filters, permitting binding studies between simian virus 40 T-antigen and chromatin to be performed. Approximately two to three times as much T-antigen was required to bind chromatin as to bind an equivalent amount of free DNA. When T-antigen was present in excess, both chromatin and free DNA were quantitatively retained on the filters. On the other hand, when DNA or chromatin was present in excess, only one-third as much chromatin as DNA was retained. We suggest that T-antigen-chromatin complexes may be formed by the cooperative binding of T-antigen to chromatin, whereas T-antigen-DNA complexes may be formed by simple bimolecular interactions.     

Plasmids of the cyanobacterium Synechocystis 6701

Abstract Plasmids were obtained from Synechocystis 6701 using a lysis method that employed a hemicellulase digestion procedure. Eight major bands were observed in the initial preparation. Four of the smaller plasmids were isolated using preparative agarose electrophoresis gels and identified by restriction endonuclease analysis. Chromosomal DNA was screened with 15 restriction enzymes and 6 ( Eco RI, Sst I, Hpa I, Bst EII, Acc I, and Bgl II) were effective. Analysis of DNA fragments from plasmids pSCY 1–4 indicated that each plasmid was unique and that their approximate sizes were 5, 7.5, 13.5 and 15 kb, respectively. Digestion of pSCY 1 and pSCY 4 with Bgl II produced DNA fragments that may be used to construct a conjugation vector for this unicellular cyanobacterium.     

SV40 viral minichromosome: preferential exposure of the origin of replication as probed by restriction endonucleases.

Isolated SV40 minichromosomes [1-3] were treated with different single-cut restriction endonucleases to probe the arrangement of nucleosomes in relation to the SV70 DNA sequence. While Eco RI and Bam HI each cut 22-27% of the SV40 minichromosomes under limit-digest conditions, Bgl I, which cuts SV40 DNA at or very near the origin of replication [4,5], cleaves 90-95% of the minichromosomes in a preparation. Similar results were obtained with minichromosomes which had been fixed with formaldehyde before endonuclease treatment. One possible interpretation of these findings is that the arrangement of nucleosomes in the compact SV40 minichromosomes is nonrandom at least with regard to sequences near the origin of DNA replication.     

Staphylococcal nuclease makes a single non-random cut in the simian virus 40 viral minichromosome.

When compact simian virus 40 (SV40) minichromosomes are treated with staphylococcal nuclease at 0 °C under limit-digest conditions, about one-third of the minichromosomes remain resistant to nuclease, a third of them are nicked, while the remaining third suffer one and only one double-stranded cut. Results show that each cleaved minichromosome is cut only once and afterwards becomes resistant to further fragmentation. This is in marked contrast to the action of staphylococcal nuclease at 37 °C, which leads to a rapid fragmentation of all minichromosomes to oligo- and mononucleosomes.The SV40 linear DNA III produced by low-temperature nuclease digestion of minichromosomes was redigested with single-cut restriction endonucleases. By this mapping procedure it was determined that the location of the staphylococcal nuclease cut is neither unique nor random; it occurs at a number of discrete sites on the DNA, half of all cuts being concentrated at the origin of replication and nearby in the “late” portion of the SV40 genome. Control experiments have shown that when staphylococcal nuclease digests naked SV40 DNA at 0 °C it does not “hesitate” after the first cut. Although initial cuts in the purified DNA are non-random in location, their distribution is quite different from that generated by a low-temperature nuclease digestion of compact SV40 minichromosomes. Possible interpretations of these results are discussed in view of the recent finding that a specific region of the SV40 genome is uniquely exposed in the minichromosome (Varshavsky et al., 1978, 1979; Scott &; Wigmore, 1978).     

Localization of T-antigen on simian virus 40 minichromosomes by immunoelectron microscopy.

SV40 chromatin extracted from 42 h post-infected cells by a modification of the standard Triton X-100-EDTA procedure and purified on neutral sucrose gradients was partially immunoprecipitable by a specific SV40 T-antigen (T-Ag) antiserum. Electron microscopic observations of spread minichromosomes were made after labelling by the indirect colloidal gold immunological method using monoclonal antibodies specific for the SV40 T-Ag. In 1-2% of morphologically mature minichromosomes the labelling corresponding to tightly bound T-Ag was localized within the nucleosome-free region near one of its borders. Mapping with three single-cut restriction endonucleases: BamHI, EcoRI and BglI localized the labelling near to, or at the origin of, replication. In addition, we observed that the T-Ag specific antibodies were linked to a DNA-bound particle when the region was not masked by a large clump of antibodies. The variable size of this particle led us to suggest that it might be a complex of T-Ag with other proteins.     

人工雌核发育草鱼近交F1代线粒体DNA限制性内切酶分析

结合差速离心法、饱和酚／氯仿／异戊醇抽提等技术．提取并纯化了雌核发育草鱼近交F．代的线粒体DNA(mtDNA)．用8种限制性内切酶对mtDNA酶切分析．结果表明：雌核发育草鱼近交Fl代mtDNA分子大小为16、77kb,除无sail酶切位点外,其余7种酶EcoRI、BalI、。YbaI、BarnHI、PstI、XhoI各产生4、4、3、3、3、2、2个切点。与已报道的普通草鱼一致．雌核发育草鱼近交F1代与普通草鱼间未检测出限制性片断长度多态性差异、这表明,雌核发育草鱼F。代与普通草鱼mtDNA遗传结构具有同一性、     

Isolation of Z-DNA binding proteins from SV40 minichromosomes: evidence for binding to the viral control region

Proteins dissociated from SV40 minichromosomes by increasing NaCl concentration were tested for their binding to Z-DNA [Br-poly(dG-dC)] and B-DNA [poly (dG-dC)]. Z-DNA binding proteins are largely released in 0.2 M NaCl whereas most B-DNA binding proteins are not released until 0.6 M NaCl. Incubation of SV40 minichromosomes with Z-DNA-Sephadex in low salt solution results in proteins with Z-DNA binding activity (PZ proteins). These proteins bind to negatively supercoiled DNAs containing left-handed Z-DNA but not to relaxed DNAs. They compete with anti-Z-DNA antibodies in binding to negatively supercoiled DNAs. The binding is tighter to negatively supercoiled SV40 DNA than to other plasmids, suggesting sequence-specific Z-DNA binding. PZ proteins binding to negatively supercoiled SV40 DNA interfere with cleavage at the Sph I sites, within the 72 bp repeat sequences of the viral control region, but not with cleavage at the Bgl I site, at the origin of replication. Removal of PZ proteins also exposes the Sph I sites in the SV40 minichromosomes while addition of PZ proteins makes the sites inaccessible.     

DNAaseI-hypersensitive minichromosomes of SV40 possess an elastic torsional strain in DNA.

Previously, we have shown that DNA in a small fraction (2-5%) of SV40 minichromosomes was torsionally strained and could be relaxed by treating minichromosomes with topoisomerase I. This fraction was enriched with endogeneous RNA polymerase II (Luchnik et al., 1982, EMBO J., 1, 1353). Here we show that one and the same fraction of SV40 minichromosomes is hypersensitive to DNAase I and is relaxable by topoisomerase I. Moreover, this fraction completely loses its hypersensitivity to DNAase I upon relaxation. The possibility that this fraction of minichromosomes can be represented by naked DNA is ruled out by the results of studying the kinetics of minichromosome digestion by DNAase I in comparison to digestion of pure SV40 DNA and by measuring the buoyant density of SV40 chromatin in equilibrium CsCl gradient. Our data obtained with SV40 minichromosomes may be relevant to the mechanism responsible for DNAase I hypersensitivity in the loops or domains of cellular chromatin.     

Effect of X-ray induced DNA damage on DNAase I hypersensitivity of SV40 chromatin: relation to elastic torsional strain in DNA.

The effect of X-irradiation on DNAase I hypersensitivity of SV40 minichromosomes within nuclei or free in solution was investigated. The susceptibility of the specific DNA sites in the control region of minichromosomes to DNAase I decreased in a dose dependent manner after irradiation of isolated nuclei. On the other hand, the irradiation of minichromosomes extracted from nuclei in 0.1 M NaCl-containing buffer almost did not affect the level of their hypersensitivity to DNAase I. This suggests that DNAase I hypersensitivity may be determined by two different mechanisms. One of them may be connected with elastic torsional strain within a fraction of minichromosomes and another seems to be determined by nucleosome free region. The first mechanism may be primarily responsible for the hypersensitivity of minichromosomes within nuclei. After irradiation of the intact cells, DNAase I hypersensitivity tested in nuclei substantially increased. This was connected with activation of endogeneous nucleases by X-irradiation which led to accumulation of single- and double-strand breaks superimposed to DNAase I induced breaks in the control region of SV40 DNA.     

Genome organization of RNA tumor viruses II. Physical maps of in vitro-synthesized Moloney murine leukemia virus double-stranded DNA by restriction endonucleases.

Physical maps of the genome of Moloney murine leukemia virus (M-MLV) DNA were constructed by using bacterial restriction endonucleases. The in vitro-synthesized M-MLV double-stranded DNA was used as the source of the viral DNA. Restriction endonucleases Sal I and Hind III cleave viral DNA at only one site and, thus, generate two DNA fragments. The two DNA fragments generated by Sal I are Sal IA (molecular weight, 3.5 x 10(6)) and Sal IB (molecular weight, 2.4 x 10(6)) and by Hind III are Hind IIIA (molecular weight, 3.6 x 10(6) and Hind IIIB (molecular weight, 2.3 x 10(6)). Restriction endonuclease Bam I generates four fragments of molecular weights of 2.1 x 10(6) (Bam IA), 2 X 10(6) (Bam IB), 1.25 X 10(6) (Bam IC), and 0.24 x 10(6) (Bam ID), whereas restriction endonuclease Hpa I cleaves the M-MLV double-stranded DNA twice to give three fragments of molecular weights of 4.4 x 10(6) (Hpa IA), 0.84 X 10(6) (Hpa IB), and 0.74 x 10(6) (Hpa IC). Digestion of M-MLV double-stranded DNA with restriction endonuclease Sma I produces four fragments of molecular weights of 3.9 x 10(6) (Sma IA), 1.3 X 10(6) (Sma IB), 0.28 X 10(6) (Sma IC), and 0.21 x 10(6) (Sma ID). A mixture of restriction endonucleases Bgl I and Bgl II (Bgl I + II) cleaves the viral DNA at four sites generating five fragments of approximate molecular weights of 2 x 10(6) (Bgl + IIA), 1.75 X 10(6) (Bgl I + IIB), 1.25 X 10(6) (Bgl I + IIC), 0.40 X 10(6) (Bgl I + IID), and 0.31 x 10(6) (Bgl I + IIE). The order of the fragments in relation to the 5' end and 3' end of the genome was determined either by using fractional-length M-MLV double-stranded DNA for digestion by restriction endonucleases or by redigestion of Sal IA, Sal IB, Hind IIIA, and Hind IIIB fragments with other restriction endonucleases. In addition, a number of other restriction endonucleases that cleave in vitro-synthesized M-MLV double-stranded DNA have also been listed.     

Localization of ribulose 1,5-bisphosphate carboxylase/oxygenase in the N2-fixing cyanobacterium Anabaena cylindrica

Abstract A new, high copy number conjugative plasmid pSLG3 (10.9 kb) was isolated from vegetative mycelium of Streptomyces lavendulae-grasserius RIA746. The sensitivity of pSLG3 DNA to 9 restriction endonucleases was tested and the positions of the unique Bgl II and Pst I target site, 3 Kpn I target sites and 5 Pvu II target sites were mapped. The unique Bgl II target site was localized outside pSLG3 essential region and was used for the construction of recombinant plasmid pSR1, composed of pSLG3 and pIJ350 Streptomyces DNAs.     

SV40 chromatin structure is not essential for viral gene expression

The biological activity and the fate of SV40 DNA (minichromosomes, DNA I, DNA II, DNA III) were tested in culture cells by immunofluorescence staining and blot analysis. Following microinjection of 2-4 circular SV40 molecules (minichromosomes, DNA I, DNA II) into the cytoplasm or the nuclei of monkey and rat cells, T- and V-antigen synthesis was demonstrable in nearly every recipient cell. Only linear DNA induced T-antigen synthesis with a very low efficiency after cytoplasmic injection. This low activity correlates with a rapid degradation of DNA III in the recipient cells. Further modifications observed immediately after injection are relaxation of superhelical molecules and formation of high-Mr DNA. Assembly of the injected DNA into SV40 chromatin-like structure, however, occurred only late after early viral gene expression.     

Disruption of the nucleosomes at the replication fork.

The fate of parental nucleosomes during chromatin replication was studied in vitro using in vitro assembled chromatin containing the whole SV40 genome as well as salt-treated and native SV40 minichromosomes. In vitro assembled minichromosomes were able to replicate efficiently in vitro, when the DNA was preincubated with T-antigen, a cytosolic S100 extract and three deoxynucleoside triphosphates prior to chromatin assembly, indicating that the origin has to be free of nucleosomes for replication initiation. The chromatin structure of the newly synthesized daughter strands in replicating molecules was analysed by psoralen cross-linking of the DNA and by micrococcal nuclease digestion. A 5- and 10-fold excess of protein-free competitor DNA present during minichromosome replication traps the segregating histones. In opposition to published data this suggests that the parental histones remain only loosely or not attached to the DNA in the region of the replication fork. Replication in the putative absence of free histones shows that a subnucleosomal particle is randomly assembled on the daughter strands. The data are compatible with the formation of a H3/H4 tetramer complex under these conditions, supporting the notion that under physiological conditions nucleosome core assembly on the newly synthesized daughter strands occurs by the binding of H2A/H2B dimers to a H3/H4 tetramer complex.     

Simple and highly efficient site-specific mutagenesis, by ligation of an oligodeoxyribonucleotide into gapped heteroduplex DNA in which the template strand contains deoxyuridine

A simple and highly efficient procedure for oligodeoxynucleotide (oligo)-directed mutagenesis has been developed. In this procedure, a gapped heteroduplex DNA is first constructed and purified. The gapped heteroduplex consists of a circular 'template' strand of DNA, which contains some misincorporated deoxyuridine nucleotides, and a complementary strand which does not contain deoxyuridine, and which lacks a defined segment. Making a specific change in the sequence of the DNA within the gapped region then only requires ligation and transformation. An oligo, exactly the same length as the gap, and with the desired sequence, is synthesized, purified, and ligated directly into the gap in the heteroduplex. When this DNA is used to transform wt (ung+) Escherichia coli, about 80% of the resulting plasmids contain the sequence determined by the synthetic oligo. One gapped heteroduplex preparation can be used for many mutagenesis experiments, so that this procedure is well-suited for producing a series of defined mutations within a defined target region flanked by sites for restriction enzyme cleavage. As the method does not require a polymerase, the effects of primer displacement and polymerase infidelity are avoided.     

Mapping the in vivo arrangement of nucleosomes on simian virus 40 chromatin by the photoaddition of radioactive hydroxymethyltrimethylpsoralen.

Intracellular simian virus 40 (SV40) chromatin was photoreacted with a 3H-labeled psoralen derivative, hydroxymethyltrimethylpsoralen (HMT), at 48 h postinfection. Psoralen compounds have been shown to readily penetrate intact cells and, in the presence of long-wavelength UV light, form covalent adducts to DNA, preferentially at regions unprotected by nucleosomes. The average distribution pattern of [3H]HMT on the SV40 genome was determined by specific activity measurements of the DNA fragments generated by HindIII plus HpaII or by AtuI restriction enzyme digestion. At levels of 1 to 10 [3H]HMT photoadducts per SV40 molecule, the radiolabel was found to be distributed nonrandomly. Comparison of the labeling pattern in vivo with that of purified SV40 DNA labeled in vitro revealed one major difference. A region of approximately 400 base pairs, located between 0.65 and 0.73 on the physical map, was preferentially labeled under in vivo conditions. This finding strongly suggests that the highly accessible region near the origin of replication, previously observed on isolated SV40 "minichromosomes," exists on SV40 chromatin in vivo during a lytic infection.